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eyes:logics:classification [2017/06/06 17:00] nfische [Modes] |
eyes:logics:classification [2017/06/12 17:27] nfische [Example] |
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=====Usage===== | =====Usage===== | ||
- | A prerequisite for a feasible **classification** is a complexity reduction of the given input dataset. This can be achieved by performing a [[:eyes:logics:pca]]. The PCA can be carried out either internally by the classification-logic or beforehand by the respective PCA logic. Additionally, the user has to define the input set and the number of expected classes/clusters. Now, the logic will split the dataset according to the information provided by the PCA into as many classes/clusters as determined aiming for minimal variance within each class/cluster. | + | A prerequisite for a feasible **classification** is a complexity reduction of the given input dataset. This can be achieved by performing a [[:eyes:logics:pca]]. The PCA can be carried out either internally by the classification-logic or beforehand by the respective PCA logic. Additionally, the user has to define the input set and the number of expected classes/clusters. Now, the logic will split the dataset according to the information provided by the PCA into as many classes/clusters as determined aiming for an optimum of i) minimal variance within each class/cluster and ii) a maximized signal-to-noise ratio. |
- | ===== Example ==== | ||
- | FIXME | ||
===== Modes ===== | ===== Modes ===== | ||
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| Eigen images location | Define, whether the Eigen images used for complexity reduction are generated on-the-fly internally (intern) or provided by an input from en external source (extern) | | | Eigen images location | Define, whether the Eigen images used for complexity reduction are generated on-the-fly internally (intern) or provided by an input from en external source (extern) | | ||
| -> Number of eigen images | How many Eigen images (and therefore dimensions) should be used as components during linear combination | | | -> Number of eigen images | How many Eigen images (and therefore dimensions) should be used as components during linear combination | | ||
- | | Split up method | Determine, whether large classes should be slip up into smaller classes due to their number of containing objects (size) or due to their high internal variance of the cross-correlation-coefficients (cccVariance) | | + | | Split up method | Determine, whether large classes should be split into smaller classes i) to obtain classes containing a similar number of images/volumes (Cluster size) or ii) to minimize internal variance within each class, as measured by the cross-correlation-coefficients (cccVariance) | |
| Number of classes | Number of resulting classes/clusters | | | Number of classes | Number of resulting classes/clusters | | ||
| Remove duplicated images | Duplicate images identified by the classification are removed | | | Remove duplicated images | Duplicate images identified by the classification are removed | | ||
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===== Concept ===== | ===== Concept ===== | ||
- | Once clusters/classes of images are found, they can be averaged (see [[eyes:logics:SumByClassNumber]]) to improve the signal-to-noise-ration substantially.((van Heel, M. (1984). Multivariate statistical classification of noisy images (randomly oriented biological macromolecules). Ultramicroscopy, 13(1-2), 165–83. Retrieved from http://www.ncbi.nlm.nih.gov/pubmed/6382731)) | + | Once clusters/classes of images are found, they can be averaged (see [[eyes:logics:SumByClassNumber]]) to improve the signal-to-noise-ratio substantially.((van Heel, M. (1984). Multivariate statistical classification of noisy images (randomly oriented biological macromolecules). Ultramicroscopy, 13(1-2), 165–83. Retrieved from http://www.ncbi.nlm.nih.gov/pubmed/6382731)) |